DE3830172A1 - METHOD FOR PRODUCING AN ACOUSTIC CARBON MEMBRANE - Google Patents

Description

The invention relates to a method for producing a acoustic carbon membrane made from carbonaceous Materials. In particular, the invention relates a method of making an acoustic Carbon membrane made of carbon-containing materials, the light weight, high elasticity, high Sound transmission speed and excellent Rigidity compared to a common membrane material, has used as a speaker and as a microphone less deformation due to an external force low sound distortion, a wide sound reproduction range, and a clear sound quality that is suitable for a digital Sound frequency age is suitable.  

It is generally desirable that a membrane for following a speaker and a voice coil support Conditions are sufficient:

• (1) low density;
• (2) large modulus of elasticity,
• (3) high propagation speed of longitudinal waves,
• (4) sufficiently large internal vibration loss, and
• (5) Stability to change the atmospheric conditions, no deformation or changing properties.

In particular, the material for the membrane should be one have a wide sound reproduction range, with high Fidelity over a wide frequency band is reproduced. For efficient and clear generation of clay quality, the material is said to have high rigidity have no deformation, such as a Creep in external stresses and the like a high speed of sound propagation. To the Increase the speed of sound based on the equation

V = (E / rho) ^1/2

where V : speed of sound, E : modulus of elasticity, rho: density, results in a material of low density and with a high modulus of elasticity.

The materials used are paper (cellulose), plastic and also contain glass fibers, carbon fiber, which is mixed together with their base material, or which are processed with metallic aluminum, titanium, magnesium, beryllium or boron, metal alloys, metal nitride, metal carbide or metal boride. However, paper, plastic and their composites have a small modulus of elasticity and low density. The speeds of sound in these materials are therefore low. Vibration division occurs in a specific mode and the frequency characteristics in the high frequency band of the materials are particularly low, which leads to a difficulty in producing a clear sound quality. In addition, these materials are easily affected by external conditions such as temperature and humidity, causing deterioration in quality and aging fatigue, thereby disadvantageously reducing the characteristics. If, on the other hand, the materials use metal plates made of aluminum, magnesium and titanium, the speeds of sound in the materials are greater than in paper or plastic, but since the materials have a low E / rho value and a low internal vibration loss, the materials have a sharp Formation of resonance in the high frequency band or an aging fatigue, such as creep, occurs in the materials, whereby the characteristic curves are disadvantageously deteriorated. Beryllium or boron provide excellent physical properties. Tweeters that use these materials as membranes extend the playback limit into audible frequency bands or higher, whereby the natural sound quality is generated without any transitions to the signals in the audible band. However, these materials are less common and very expensive as mineral resources and cause difficulties in industrial processing. These methods make it difficult to manufacture large-size speakers.

In addition to these materials, attempts are being made to obtain membranes made of carbon-containing material due to the large E / rho value of the carbon materials. That is, there is

• (1) a process to make a resin sheet or a Charring resin sheet alone in graphite;
• (2) a process for molding and charring in graphite of a composite material made of resin and various carbon-containing powders; and
• (3) a method to make one with carbon fibers carbonize reinforced plastic in graphite.

Because the process (1) has a low carbon yield of the plastic material used is a precise product not only hardly received, but one Product with a high modulus of elasticity, such as graphite or carbon fiber cannot be made from plastic obtained carbon can be obtained.

The method (2) can be a product with high Provide modulus of elasticity compared to method (1),  using graphite or carbon fiber because however, it used various resins to control the Improving formability is the ratio of Resin carbon to the calcined material so large that a reduction in the elastic modulus of the Carbon fiber or graphite is caused.

Since only the carbon content baked in process (3) and contract when the carbon fiber Reinforced plastic is calcined, countless fine cracks under the carbon fibers so that a product in which the carbon fiber and the Resin carbon without defects are not preserved can be. So there is such a disadvantage that the function of the carbon fiber is lost.

It is therefore the object of the invention to provide a method for producing an acoustic carbon membrane from carbon-containing materials which eliminates the disadvantages of the materials for the known membranes mentioned above, the membrane consisting of a carbon material which has a large E / rho value has, and the carbon material has high elasticity and is inexpensively manufactured industrially with high elasticity and high accuracy without cracks.

The task mentioned at the outset is based on the Investigations of the inventor by a method for  Manufacture from an acoustic carbon membrane carbon-containing materials solved, the invention is characterized by the following steps: uniform Separation of thermally deposited in the vapor phase Carbon produced by the thermal decomposition of a together with the carrier gas introduced hydrocarbon was generated on the surface layer of a membrane-shaped base material; and severing of the obtained, thermally deposited Carbon separation from the membrane-shaped base material.

Since the obtained by the inventive method Carbon membrane of the shape of the base material follows, the size and shape accuracy of the membrane maintained to a high degree and delivered a membrane, the high elasticity and high speed of sound propagation along with light weight and less distortion having.

A method for producing an inventive Acoustic carbon membrane will now be explained.

A base material with a membrane shape that can be processed of metal, such as iron or copper, and Cutting a graphite block is obtained first through an induction heating system that works with a High frequency induction furnace works or through one Heating system that works with a side tube furnace, heated, hydrocarbon material is together with Carrier gas such as argon, etc. in contact with the heated base material introduced to the  thermally decompose heated hydrocarbon and Carbon is generated and separated.

The hydrocarbon material is methane, propane, benzene, Acetylene, etc., can be used. If ethylene chloride, for example 1,1-dichlorethylene, cis-1,2-dichlorethylene, trans-1,2-dichlorethylene, 1,1,2-trichlorethylene, and Ethane chloride, such as 1,1-dichloroethane, 1,2-dichloroethane, 1,1,1-trichloroethane, 1,1,2-trichloroethane etc., used to thermally at low temperature being dismantled becomes a thermally separated one Obtained carbon at 1100 ° C and preferably 900 ° C, which improves productivity.

In this case it is important to leave all areas without Keep temperature gradients at the same temperature. The thermally deposited carbon, the through the thermal decomposition of the together with the Carrier gas introduced material was obtained be deposited evenly on the surface layer.

The hydrocarbon concentration in the carrier gas depends on the temperature of the base material, the gas pressure and the speed, and 20 vol.% are in the Practice preferred. The higher the temperature of the Base material, the lower the required Concentration. The concentration is increased if the gas pressure in a vessel to generate the thermal deposited carbon is less. So the higher the velocity of the gas flow is the greater can be concentration. To speed up the  Deposition speed becomes the material concentration elevated. It is to increase the carbon yield effective to reduce the gas flow rate. The thermal Carbon can be separated by these measures a maximum deposition rate of several mm / h can be obtained.

The elasticity value of the carbon material is generally 0.5 to 1.5 × 10 ⁶ g / mm ² , the elasticity value of the hard carbon material such as glassy carbon obtained by the carbonization of the thermosetting resin is 2.0 to 3.3 × 10 ⁶ g / mm ² , and the elasticity of the thermally deposited carbon is less than 3.0 to 6.0 × 10 ⁶ g / mm ² . Therefore, according to the invention, a membrane having a higher elasticity can be obtained as the product than when the resin is molded and converted into carbon.

Then the thermal deposition separated carbon separated from the base material. The separation takes place by cooling or heating again and cooling again using the thermal Expansion coefficient of the base material and thermally deposited carbon or by cutting and removing the base material. in case of a metal base material is separated by Dissolve with a solvent or melt high temperature. In this way, a membrane can be obtained only from the thermally deposited Carbon exists. The carbon membrane obtained can exactly follow the shape and size of the base material.  The carbon membrane obtained is, as required, graphitized.

It will refer to the description of the preferred embodiments Referred. The invention is illustrated by exemplary embodiments of a method for producing an acoustic Carbon membrane described, however, it is not limited to the respective embodiments.

example 1

An artificial graphite block was cut to fit one Obtain base material with membrane shape.

This basic material was then replaced by a Induction heating system that heats up with a High frequency induction furnace works, and a thermal Carbon deposited was on the surface layer of the base material. It was used Material cis-1,2-dichlorethylene, the carrier gas used Argon gas, the material concentration was 13 vol.%, The Gas flow rate was 380 ml / min, the temperature of the Base material was kept at 880 ° C, and the thermally deposited carbon was during 0.3 Hours separated. The graphite obtained and the thermally deposited carbon were summarized, cooled quickly, heated quickly, and thermally deposited carbon was separated from the base material. Because doing so, a small amount of graphite powder on the  thermally deposited carbon existing membrane side stuck, it was cut away and removed.

The membrane obtained was 40 microns thick and followed exactly the shape and size of the base material.

A flat test piece with the same thickness was produced under the same conditions as this membrane and different values were measured. The density was 2.0 g / cm ³ , the elasticity was 52 GPa, and the speed of sound was 5100 m / s.

Example 2

A block of graphite-silica-alumina was made cut to a base material with membrane shape to obtain.

Then the base material was replaced by an external heating system, that works with a side tube furnace, heats, and a thermally deposited carbon was on the The surface layer of the base material is deposited. Here the material used was propane, the carrier gas used Argon gas, the material concentration was 16% by volume Gas flow rate was 420 ml / min, the temperature of the Base material was kept at 200 ° C, and the thermally deposited carbon was during 0.3 Hours separated. The graphite obtained and the thermal deposited carbon was pooled quickly  cooled, quickly heated and the thermally separated Carbon was separated from the base material. The obtained material was in a nitrogen gas atmosphere heated to 2200 ° C. The membrane obtained in this way was 60 microns thick and exactly followed the shape and size of the base material.

A flat specimen of the same thickness was produced under the same conditions as the membrane, and different values were measured. The density was 2.1 g / cm ³ , the elasticity was 63 GPa and the speed of sound was 5480 m / s.

Claims (5)

1. A method for producing an acoustic carbon membrane from carbon-containing materials, characterized by the following steps:
uniform deposition of carbon thermally deposited in the vapor phase, which was generated by the thermal decomposition of a hydrocarbon introduced together with the carrier gas, on the surface layer of a membrane-shaped base material; and
Separation of the thermally deposited carbon deposit obtained from the membrane-shaped base material. 2. The method according to claim 1, characterized characterized in that the hydrocarbon serves a thermally deposited Carbon by vapor phase conversion to To get carbon. 3. The method according to claim 2, characterized characterized in that the hydrocarbon is selected from the group consisting of methane, propane, There is benzene and acetylene. 4. The method according to claim 2, characterized characterized in that the hydrocarbon is selected from the group consisting of ethylene chloride, such as 1,1-dichlorethylene, cis-1,2-dichlorethylene, trans-1,2-dichlorethylene, 1,1,2-trichlorethylene, and ethane chloride, such as 1,1-dichloroethane, 1,2-dichloroethane, 1,1,1-trichloroethane, 1,1,2-trichloroethane etc. exists. 5. The method according to claim 1, characterized characterized in that the carrier gas an inert gas, such as hydrogen gas, is nitrogen gas or argon gas etc.